INRA, UR 1268 Biopolymers Interactions and Assemblies (BIA), 44316 Nantes, France.
Montpellier SupAgro-INRA-UM-CIRAD, JRU IATE 1208, 34060 Montpellier, France.
Food Res Int. 2018 Jun;108:203-215. doi: 10.1016/j.foodres.2018.03.027. Epub 2018 Mar 16.
Dehulled yellow pea flour (48.2% starch, 23.4% proteins, d.b.), was processed by a twin-screw extruder at various moisture contents MC (18-35% w.b.), product temperature T (115-165 °C), and specific mechanical energy SME (50-1200 kJ/kg). Structural changes of extruded pea flour were determined at different scales by measurements of density (expansion), crystallinity (X-ray diffraction), gelatinisation enthalpy (DSC), starch solubility in water and protein solubility in SDS and DTE (SE-HPLC). Foam density dropped from 820 to 85 kg/m with increase in SME and T (R ≥ 0.78). DSC and XRD results showed that starch was amorphous whatever extrusion conditions. Its solubility in water augmented up to 50%. Increasing temperature from 115 to 165 °C decreased proteins soluble in SDS from 95 to 35% (R = 0.83) of total proteins, whereas the proteins soluble in DTE increased from 5 to 45% (R = 0.75) of total proteins. These trends could be described by sigmoid models, which allowed determining onset temperatures for changes of protein solubility in the interval [125, 146 °C], whatever moisture content. The SME impact on protein solubility followed similar trends. These results suggest the creation of protein network by SS bonds, implicating larger SDS-insoluble protein aggregates, as a result of increasing T and SME, accompanied by creation of covalent bonds other than SS ones. CSLM images suggested that extruded pea flour had a composite morphology that changed from dispersed small protein aggregates to a bi-continuous matrix of large protein aggregates and amorphous starch. This morphology would govern the expansion of pea flour by extrusion.
脱壳黄豌豆粉(淀粉含量 48.2%,蛋白质含量 23.4%,干基)在不同的水分含量(18-35%湿基)、产品温度(115-165°C)和比机械能(50-1200kJ/kg)下,通过双螺杆挤出机进行加工。通过测量密度(膨胀)、结晶度(X 射线衍射)、糊化焓(DSC)、淀粉在水中的溶解度以及 SDS 和 DTE 中的蛋白质溶解度(SE-HPLC),在不同尺度上确定了挤出豌豆粉的结构变化。随着 SME 和 T 的增加(R≥0.78),泡沫密度从 820 降低到 85kg/m3。无论挤出条件如何,DSC 和 XRD 结果均表明淀粉呈非晶态。其在水中的溶解度增加到 50%。从 115°C 升高到 165°C,SDS 中可溶蛋白从总蛋白的 95%降低到 35%(R=0.83),而 DTE 中可溶蛋白从总蛋白的 5%增加到 45%(R=0.75)。这些趋势可以用 S 型模型来描述,无论水分含量如何,该模型都可以确定蛋白质溶解度变化的起始温度在[125,146°C]之间。SME 对蛋白质溶解度的影响也遵循类似的趋势。这些结果表明,随着 T 和 SME 的增加,SS 键会形成蛋白质网络,导致 SDS 不溶性蛋白质聚集物变大,同时还会形成除 SS 键以外的共价键。CSLM 图像表明,挤出的豌豆粉具有复合形态,从分散的小蛋白质聚集物转变为大蛋白质聚集物和无定形淀粉的双连续基质。这种形态将控制豌豆粉的挤出膨胀。
